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Automobile traffic: A source of PCBs to the atmosphere
Chemosphere, Vd.23, No.6, Printed in Great Britain
pp 785-788,1991
0045-6535/91 $3.00 + 0.00 Pergamon Press plc
AUTOMOBILE TRAFFIC : A SOURCE OF PCBs TO THE ATNOSPHERE
Laurent GRANIER and Marc CHEVREUIL I n s t i t u t d'Hydrologie et de Climatologie, Laboratoire de Chimie Analytique et d'Hydrologie Gdn6rale, Universit~ Paris 6, 4 place Jussieu, B.P. 122, 75252 Paris Cedex 05, France.
Abstract - Air samples from a road tunnel showed that automobile t r a f f i c could be a source of PCBs in the atmosphere. Contrary to what was observed on ambient a i r samples, the PCBs were mainly on particulates, and showed a characteristic chromatographic pattern. INTRODUCTION - The most commonly reported PCB sources are emission by municipal or industrial incinerators and v o l a t i l i s a t i o n from l a n d f i l l s or s o i l s (W.H.O., 1978). Three clues allowed us to believe that automobile t r a f f i c could be a source of these pollutants : i ) newspapers have reported t r a f f i c
of o i l products contaminated by PCBs in France ( c i t y of Limoges) and between
Canada and the U.S.A. ("Le Monde" 01.14.1989 and 05.14.1989);
ii)
in an area of high t r a f f i c
density, we had measured higher PCB concentrations at 10 meters then at 55 meters height (Chevreuil
and Granier, 1990), i i i )
Mazzone and Nicoud (1987) had established a positive
correlation between the contamination of s o i l s by PCBs and the proximity of roadways. We report here on measurements in a road tunnel,
in order to assess the p o s s i b i l i t y of
automotive emission of PCBs. MATERIALS AND METHODS
Sampling ( F i g . 1) The "Tunnel
of the Tuileries"
i s 800 m long and taken by 50,000 cars per day.
were taken b i m o n t h l y d u r i n g maximum t r a f f i c
Four samples
from mondays t o f r i d a y s between 8 and 10 a,m. and
between 3 and 9 p.m.. Bimonthly samples were taken s i m u l t a n e o u s l y on the t o p o f the S a i n t Jacques Tower (55 m h i g h ) and on the U n i v e r s i t y Campus (15 m h i g h ) .
785
786
Figure 1 :
~
/"/ -
sampling p o i n t s
Analyt ica l procedure
3
~'~'~X~ ! I
2 Uniwms~y~ s 3 ~nnel ~ the ~ i l e r i ~
250 to 400 m3 of a i r are pulled through a glass f i b e r
filter
Whatman GF/F followed by a
cartridge f i l l e d with XAD-2 Amberlite resin. The XAD-2 is soxhlet extracted during 96 hours by a mixture of hexane and d i e t h y l e t h e r 90:10. F i l t e r s are cut in s t r i p s and put to r e f l u x during 12 hours with methylchloride. The extracts are concentrated t o 20 ml and p u r i f i e d with 2-3 ml of fuming HzS04 (7 %). The analysis is performed by HRGC on SPB5 column ( l = 30 m, i . d . = 0.25 mm, f i l m = 0.25 IJm), with an ECD detector. The q u a n t i f i c a t i o n of t o t a l PCBs is made by comparison t o a 1:1:1 mixture of Aroclors 1242, 1254 and 1268. Components I.U.P.A.C. n" 18, 28, 52, 60, 101, 153, 138 and 180 were quantified individually. Detection l i m i t s f o r t o t a l PCBs are 0.2 ng.m-s f o r the vapor phase and 0.05 ng.m-s f o r the p a r t i c u l a t e phase. RESULTS AND DISCUSSION
The results of t o t a l PCBs in the tunnel and in ambient a i r (Saint Jacques Tower and Campus) are displayed in the table I.
Table 1 : PCBconcentrations (ng.m-3) in particulate and vapor phases in the roadway tunnel. Comparisonwith ambient air average concentrations at the Saint Jacques Towerand the University Campus. localization
vapor p h a s e
particulate phase
total
roadway tunnel 03.19-29.1990 04.02-14.1990 04.13-24.1990 05.14-28.1990
1.3 1.9 2.5 2.7
5.9 5.6 5.8 3.7
7.2 7.5 8.3 6.4
mean
2.1
5.2
7.3
S a i n t Jacques Tower (n = 4)
1.6
0.69
2.3
Campus (n = 4)
3.8
1.0
4.8
787
The c o n c e n t r a t i o n s o f the vapor phase are s i m i l a r the e x t e r i o r
air
(mean = 2.7 ng.m-3).
phase in the tunnel
between t h e tunnel
On the c o n t r a r y ,
(mean = 2.1 ng.m-3)
PCB c o n c e n t r a t i o n s o f the p a r t i c u l a t e
are much h i g h e r (mean = 5.2 ng.m- 3 ) than In the ambient a i r
n g . m - 3 ) . They represent 71 ~ o f t o t a l
PCBs, whereas t h e p a r t i c u l a t e
1990).
In t h i s
study, t h e p a r t i c u l a t e
(mean = 0.85
phase In t h e ambient a i r
i s u s u a l l y lower than the vapor phase (see, f o r example, Eisenretch e t a l . , Bouchertall,
and
1981; Duinker and
phase amounts t o 30 % o f the t o t a l
a t the
S a i n t Jacques Tower and 21% at the U n i v e r s i t y . Figure 2 shows t y p i c a l extract.
chromatograms o f an ambient a i r f i l t e r
The p a t t e r n o f the l a t t e r
extract,
i s c l e a r l y s h i f t e d on the l e f t
TUNNEL
and o f a tunnel f i l t e r
towards l i g h t e r
components.
FILTER
F i g u r e 2 : Chromatograms o f the e x t r a c t s o f a filter
from the
Tuileries
roadway
t u n n e l and the S a i n t Jacques Tower.
AMBIENT
AIR
i-"
FILTER =
Table 2 presents the same d i f f e r e n c e under a more q u a n t i t a t i v e relative
composition
between j u l y
of
8 components in the
1989 and j u l y
particulate
aspect by comparing the average
phase o f the
Saint
Jacques Tower
1990 (n = 17) w i t h the mean o f the f o u r tunnel f i l t e r
Table 2 : Comparison between the average r e l a t i v e filters
i
and the t u n n e l f i l t e r s .
extracts.
c o m p o s i t i o n o f ambient a i r
Z o f the c o n t r i b u t i o n
components t o t h e i r
o f 8 PCB
sum.
Z.U.P.A.C. n °
18
28
52
60
101
153
138
180
S a i n t Jacques Tower (n : 18)
0
4
9
13
13
20
22
18
Tunnel (n = 4)
5
11
15
18
17
14
14
7
788
This important q u a l i t a t i v e difference shows that the preponderance of the particulate phase is not caused only by the greater amount of particulate matter in the tunnel than outside (around 200 ng.m-3 versus 50 ng.m-3). Bidleman and Foreman (1987) showed that semi-volatile organic compounds reached rapidly equilibrium between vapor and particulate phases. This could explain why the percentage of the particulate phase is not higher in urban areas. Furthermore, part of the particulate matter can possibly s e t t l e
near the source of emission on the streets,
contributing to the enrichment of street runoff by PCBs. CONCLUSION These results underscore a possible source of PCBs to the atmosphere. We could not quantify i t here with an emission factor, due to the i m p o s s i b i l i t y to evaluate the residence time of the a i r in the tunnel. The PCBs are probably o r i g i n a l l y present in o i l , gasoline or diesel. They could be emitted in vapor phase followed by a rapid adsorption.
ACKNOWLEDGEMENT - This study is part of a larger research funded by the Air Quality Agency (AQA). We are g r a t e f u l l to Mrs Petit-Coviaux, of the Laboratoire d'Hygi~ne de la V i l l e de Paris, for her assistance in the choice of the sampling points. Thierry Mellet greatly helped to improve the english of the manuscript. REFERENCES Bidleman T.F.
and Foreman W.T., 1987.- Vapor - p a r t i c l e p a r t i t i o n i n g of semivolatile organic
compounds. In "Sources and Fates of Aquatic Pollutants" (Hites R.A. and Eisenreich S.J. eds.), Adv. in Chem. Ser., Vol. 216, American Chemical Society, p. 27-56. Chevreuil
M.
and
Granier
L.,
1990.- Etude
de
la
pollution
de
l'air
par
les
polychlorobiph~nyles ~ Paris. Rapport d'~tude ~ l'Agence pour la Qualit~ de l ' A i r , 27 p. Duinker J.C. and Bouchertall F., biphenyl
1989.- On the d i s t r i b u t i o n of atmospheric polychlorinated
congeners between vapor phase, aerosols, and rain.
Environ.
Sci.
Technol.,
23 : 57-62. Eisenreich S.J.,
Looney B.B.
and Thornton J . D . ,
1981.- A i r b o r n e o r g a n i c contaminants in the
Great Lakes ecosystem. Environ. Science Technol., 15 : 30-38. Le Monde,
14/01/1989.- D~couverte
~ Limoges d'un
important
trafic
de p r o d u i t s
p~troliers
toxiques. Le Monde, 14/05/1989.- Apr~s l a d~couverte d'un t r a f i c
de d~chets t o x i q u e s ,
l e Canada c o n t r g l e
l e c a r b u r a n t en provenance des E t a t s - U n i s . Mazzone S. and Nicoud S., des s o l s
par
les
1987.- Importance de l ' ~ c h a n t i l l o n n a g e
micro-polluants
organlques.
Rapport
de
dans l ' ~ t u d e de l a p o l l u t i o n recherche
3j== c y c l e ,
Ecole
Polytechnique F~d6rale de Lausanne, 76 p. W.H.O.,
1978.- C r i t ~ r e s
d'hygi~ne
de
l'environnement
2,
P o l y c h l o r o t e r p h ~ n y l e s , 93 p.
(Received
i n Germany 15 J u l y
1991;accepted
16 A u g u s t 1 9 9 1 )
Polychlorobiph6nyles
et
pp 785-788,1991
0045-6535/91 $3.00 + 0.00 Pergamon Press plc
AUTOMOBILE TRAFFIC : A SOURCE OF PCBs TO THE ATNOSPHERE
Laurent GRANIER and Marc CHEVREUIL I n s t i t u t d'Hydrologie et de Climatologie, Laboratoire de Chimie Analytique et d'Hydrologie Gdn6rale, Universit~ Paris 6, 4 place Jussieu, B.P. 122, 75252 Paris Cedex 05, France.
Abstract - Air samples from a road tunnel showed that automobile t r a f f i c could be a source of PCBs in the atmosphere. Contrary to what was observed on ambient a i r samples, the PCBs were mainly on particulates, and showed a characteristic chromatographic pattern. INTRODUCTION - The most commonly reported PCB sources are emission by municipal or industrial incinerators and v o l a t i l i s a t i o n from l a n d f i l l s or s o i l s (W.H.O., 1978). Three clues allowed us to believe that automobile t r a f f i c could be a source of these pollutants : i ) newspapers have reported t r a f f i c
of o i l products contaminated by PCBs in France ( c i t y of Limoges) and between
Canada and the U.S.A. ("Le Monde" 01.14.1989 and 05.14.1989);
ii)
in an area of high t r a f f i c
density, we had measured higher PCB concentrations at 10 meters then at 55 meters height (Chevreuil
and Granier, 1990), i i i )
Mazzone and Nicoud (1987) had established a positive
correlation between the contamination of s o i l s by PCBs and the proximity of roadways. We report here on measurements in a road tunnel,
in order to assess the p o s s i b i l i t y of
automotive emission of PCBs. MATERIALS AND METHODS
Sampling ( F i g . 1) The "Tunnel
of the Tuileries"
i s 800 m long and taken by 50,000 cars per day.
were taken b i m o n t h l y d u r i n g maximum t r a f f i c
Four samples
from mondays t o f r i d a y s between 8 and 10 a,m. and
between 3 and 9 p.m.. Bimonthly samples were taken s i m u l t a n e o u s l y on the t o p o f the S a i n t Jacques Tower (55 m h i g h ) and on the U n i v e r s i t y Campus (15 m h i g h ) .
785
786
Figure 1 :
~
/"/ -
sampling p o i n t s
Analyt ica l procedure
3
~'~'~X~ ! I
2 Uniwms~y~ s 3 ~nnel ~ the ~ i l e r i ~
250 to 400 m3 of a i r are pulled through a glass f i b e r
filter
Whatman GF/F followed by a
cartridge f i l l e d with XAD-2 Amberlite resin. The XAD-2 is soxhlet extracted during 96 hours by a mixture of hexane and d i e t h y l e t h e r 90:10. F i l t e r s are cut in s t r i p s and put to r e f l u x during 12 hours with methylchloride. The extracts are concentrated t o 20 ml and p u r i f i e d with 2-3 ml of fuming HzS04 (7 %). The analysis is performed by HRGC on SPB5 column ( l = 30 m, i . d . = 0.25 mm, f i l m = 0.25 IJm), with an ECD detector. The q u a n t i f i c a t i o n of t o t a l PCBs is made by comparison t o a 1:1:1 mixture of Aroclors 1242, 1254 and 1268. Components I.U.P.A.C. n" 18, 28, 52, 60, 101, 153, 138 and 180 were quantified individually. Detection l i m i t s f o r t o t a l PCBs are 0.2 ng.m-s f o r the vapor phase and 0.05 ng.m-s f o r the p a r t i c u l a t e phase. RESULTS AND DISCUSSION
The results of t o t a l PCBs in the tunnel and in ambient a i r (Saint Jacques Tower and Campus) are displayed in the table I.
Table 1 : PCBconcentrations (ng.m-3) in particulate and vapor phases in the roadway tunnel. Comparisonwith ambient air average concentrations at the Saint Jacques Towerand the University Campus. localization
vapor p h a s e
particulate phase
total
roadway tunnel 03.19-29.1990 04.02-14.1990 04.13-24.1990 05.14-28.1990
1.3 1.9 2.5 2.7
5.9 5.6 5.8 3.7
7.2 7.5 8.3 6.4
mean
2.1
5.2
7.3
S a i n t Jacques Tower (n = 4)
1.6
0.69
2.3
Campus (n = 4)
3.8
1.0
4.8
787
The c o n c e n t r a t i o n s o f the vapor phase are s i m i l a r the e x t e r i o r
air
(mean = 2.7 ng.m-3).
phase in the tunnel
between t h e tunnel
On the c o n t r a r y ,
(mean = 2.1 ng.m-3)
PCB c o n c e n t r a t i o n s o f the p a r t i c u l a t e
are much h i g h e r (mean = 5.2 ng.m- 3 ) than In the ambient a i r
n g . m - 3 ) . They represent 71 ~ o f t o t a l
PCBs, whereas t h e p a r t i c u l a t e
1990).
In t h i s
study, t h e p a r t i c u l a t e
(mean = 0.85
phase In t h e ambient a i r
i s u s u a l l y lower than the vapor phase (see, f o r example, Eisenretch e t a l . , Bouchertall,
and
1981; Duinker and
phase amounts t o 30 % o f the t o t a l
a t the
S a i n t Jacques Tower and 21% at the U n i v e r s i t y . Figure 2 shows t y p i c a l extract.
chromatograms o f an ambient a i r f i l t e r
The p a t t e r n o f the l a t t e r
extract,
i s c l e a r l y s h i f t e d on the l e f t
TUNNEL
and o f a tunnel f i l t e r
towards l i g h t e r
components.
FILTER
F i g u r e 2 : Chromatograms o f the e x t r a c t s o f a filter
from the
Tuileries
roadway
t u n n e l and the S a i n t Jacques Tower.
AMBIENT
AIR
i-"
FILTER =
Table 2 presents the same d i f f e r e n c e under a more q u a n t i t a t i v e relative
composition
between j u l y
of
8 components in the
1989 and j u l y
particulate
aspect by comparing the average
phase o f the
Saint
Jacques Tower
1990 (n = 17) w i t h the mean o f the f o u r tunnel f i l t e r
Table 2 : Comparison between the average r e l a t i v e filters
i
and the t u n n e l f i l t e r s .
extracts.
c o m p o s i t i o n o f ambient a i r
Z o f the c o n t r i b u t i o n
components t o t h e i r
o f 8 PCB
sum.
Z.U.P.A.C. n °
18
28
52
60
101
153
138
180
S a i n t Jacques Tower (n : 18)
0
4
9
13
13
20
22
18
Tunnel (n = 4)
5
11
15
18
17
14
14
7
788
This important q u a l i t a t i v e difference shows that the preponderance of the particulate phase is not caused only by the greater amount of particulate matter in the tunnel than outside (around 200 ng.m-3 versus 50 ng.m-3). Bidleman and Foreman (1987) showed that semi-volatile organic compounds reached rapidly equilibrium between vapor and particulate phases. This could explain why the percentage of the particulate phase is not higher in urban areas. Furthermore, part of the particulate matter can possibly s e t t l e
near the source of emission on the streets,
contributing to the enrichment of street runoff by PCBs. CONCLUSION These results underscore a possible source of PCBs to the atmosphere. We could not quantify i t here with an emission factor, due to the i m p o s s i b i l i t y to evaluate the residence time of the a i r in the tunnel. The PCBs are probably o r i g i n a l l y present in o i l , gasoline or diesel. They could be emitted in vapor phase followed by a rapid adsorption.
ACKNOWLEDGEMENT - This study is part of a larger research funded by the Air Quality Agency (AQA). We are g r a t e f u l l to Mrs Petit-Coviaux, of the Laboratoire d'Hygi~ne de la V i l l e de Paris, for her assistance in the choice of the sampling points. Thierry Mellet greatly helped to improve the english of the manuscript. REFERENCES Bidleman T.F.
and Foreman W.T., 1987.- Vapor - p a r t i c l e p a r t i t i o n i n g of semivolatile organic
compounds. In "Sources and Fates of Aquatic Pollutants" (Hites R.A. and Eisenreich S.J. eds.), Adv. in Chem. Ser., Vol. 216, American Chemical Society, p. 27-56. Chevreuil
M.
and
Granier
L.,
1990.- Etude
de
la
pollution
de
l'air
par
les
polychlorobiph~nyles ~ Paris. Rapport d'~tude ~ l'Agence pour la Qualit~ de l ' A i r , 27 p. Duinker J.C. and Bouchertall F., biphenyl
1989.- On the d i s t r i b u t i o n of atmospheric polychlorinated
congeners between vapor phase, aerosols, and rain.
Environ.
Sci.
Technol.,
23 : 57-62. Eisenreich S.J.,
Looney B.B.
and Thornton J . D . ,
1981.- A i r b o r n e o r g a n i c contaminants in the
Great Lakes ecosystem. Environ. Science Technol., 15 : 30-38. Le Monde,
14/01/1989.- D~couverte
~ Limoges d'un
important
trafic
de p r o d u i t s
p~troliers
toxiques. Le Monde, 14/05/1989.- Apr~s l a d~couverte d'un t r a f i c
de d~chets t o x i q u e s ,
l e Canada c o n t r g l e
l e c a r b u r a n t en provenance des E t a t s - U n i s . Mazzone S. and Nicoud S., des s o l s
par
les
1987.- Importance de l ' ~ c h a n t i l l o n n a g e
micro-polluants
organlques.
Rapport
de
dans l ' ~ t u d e de l a p o l l u t i o n recherche
3j== c y c l e ,
Ecole
Polytechnique F~d6rale de Lausanne, 76 p. W.H.O.,
1978.- C r i t ~ r e s
d'hygi~ne
de
l'environnement
2,
P o l y c h l o r o t e r p h ~ n y l e s , 93 p.
(Received
i n Germany 15 J u l y
1991;accepted
16 A u g u s t 1 9 9 1 )
Polychlorobiph6nyles
et